/*
 * 86Box    A hypervisor and IBM PC system emulator that specializes in
 *          running old operating systems and software designed for IBM
 *          PC systems and compatibles from 1981 through fairly recent
 *          system designs based on the PCI bus.
 *
 *          This file is part of the 86Box distribution.
 *
 *          Implementation of the NEC uPD-765 and compatible floppy disk
 *          controller.
 *
 * Authors: Sarah Walker, <https://pcem-emulator.co.uk/>
 *          Miran Grca, <mgrca8@gmail.com>
 *          Toni Riikonen, <riikonen.toni@gmail.com>
 *
 *          Copyright 2008-2020 Sarah Walker.
 *          Copyright 2016-2020 Miran Grca.
 *          Copyright 2025 Toni Riikonen.
 */
#include <stdio.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <stdarg.h>
#include <wchar.h>
#define HAVE_STDARG_H
#include <86box/86box.h>
#include <86box/device.h>
#include "cpu.h"
#include <86box/machine.h>
#include <86box/io.h>
#include <86box/dma.h>
#include <86box/pic.h>
#include <86box/timer.h>
#include <86box/ui.h>
#include <86box/fdd.h>
#include <86box/fdc.h>
#include <86box/fdc_ext.h>
#include <86box/plat_fallthrough.h>
#include <86box/plat_unused.h>
#include <86box/fifo.h>

extern uint64_t motoron[FDD_NUM];

const uint8_t command_has_drivesel[32] = {
    0, 0,
    1, /* READ TRACK */
    0,
    1, /* SENSE DRIVE STATUS */
    1, /* WRITE DATA */
    1, /* READ DATA */
    1, /* RECALIBRATE */
    0,
    1, /* WRITE DELETED DATA */
    1, /* READ ID */
    0,
    1, /* READ DELETED DATA */
    1, /* FORMAT TRACK */
    0,
    1, /* SEEK, RELATIVE SEEK */
    0,
    1, /* SCAN EQUAL */
    0, 0, 0, 0,
    1, /* VERIFY */
    0, 0,
    1, /* SCAN LOW OR EQUAL */
    0, 0, 0,
    1, /* SCAN HIGH OR EQUAL */
    0, 0
};

static uint8_t current_drive = 0;

static void fdc_callback(void *priv);
int         lastbyte = 0;

int floppymodified[4];
int floppyrate[4];

int fdc_current[FDC_MAX] = { 0, 0 };

volatile int fdcinited = 0;

#ifdef ENABLE_FDC_LOG
int fdc_do_log = ENABLE_FDC_LOG;

static void
fdc_log(const char *fmt, ...)
{
    va_list ap;

    if (fdc_do_log) {
        va_start(ap, fmt);
        pclog_ex(fmt, ap);
        va_end(ap);
    }
}
#else
#    define fdc_log(fmt, ...)
#endif

typedef const struct {
    const device_t *device;
} fdc_cards_t;

static fdc_cards_t fdc_cards[] = {
    // clang-format off
    { &device_none               },
    { &device_internal           },
    { &fdc_xt_device             },
    { &fdc_at_device             },
    { &fdc_b215_device           },
    { &fdc_pii151b_device        },
    { &fdc_pii158b_device        },
    { &fdc_compaticard_i_device  },
    { &fdc_compaticard_ii_device },
#if 0
    { &fdc_compaticard_iv_device },
#endif
    { &fdc_monster_device        },
    { NULL                       }
    // clang-format on
};

int
fdc_card_available(int card)
{
    if (fdc_cards[card].device)
        return (device_available(fdc_cards[card].device));

    return 1;
}

const device_t *
fdc_card_getdevice(int card)
{
    return (fdc_cards[card].device);
}

int
fdc_card_has_config(int card)
{
    if (!fdc_cards[card].device)
        return 0;

    return (device_has_config(fdc_cards[card].device) ? 1 : 0);
}

const char *
fdc_card_get_internal_name(int card)
{
    return device_get_internal_name(fdc_cards[card].device);
}

int
fdc_card_get_from_internal_name(char *s)
{
    int c = 0;

    while (fdc_cards[c].device != NULL) {
        if (!strcmp(fdc_cards[c].device->internal_name, s))
            return c;
        c++;
    }

    return 0;
}

void
fdc_card_init(void)
{
    if ((fdc_current[0] > FDC_INTERNAL) && fdc_cards[fdc_current[0]].device)
        device_add_inst(fdc_cards[fdc_current[0]].device, 0);
}

uint8_t
fdc_get_current_drive(void)
{
    return current_drive;
}

void
fdc_ctrl_reset(void *priv)
{
    fdc_t *fdc = (fdc_t *) priv;

    fdc->stat             = 0x80;
    fdc->pnum = fdc->ptot = 0;
    fdc->st0              = 0;
    fdc->head             = 0;
    fdc->step             = 0;
    fdc->power_down       = 0;

    if (!fdc->lock && !fdc->fifointest) {
        fdc->fifo  = 0;
        fdc->tfifo = 1;

        fifo_reset(fdc->fifo_p);
        fifo_set_len(fdc->fifo_p, fdc->tfifo + 1);
        fifo_set_trigger_len(fdc->fifo_p, fdc->tfifo + 1);
    }
}

sector_id_t
fdc_get_read_track_sector(fdc_t *fdc)
{
    return fdc->read_track_sector;
}

int
fdc_get_compare_condition(fdc_t *fdc)
{
    switch (fdc->interrupt) {
        default:
        case 0x11:
            return 0;
        case 0x19:
            return 1;
        case 0x1D:
            return 2;
    }
}

int
fdc_is_deleted(fdc_t *fdc)
{
    return fdc->deleted & 1;
}

int
fdc_is_sk(fdc_t *fdc)
{
    return (fdc->deleted & 0x20) ? 1 : 0;
}

void
fdc_set_wrong_am(fdc_t *fdc)
{
    fdc->wrong_am = 1;
}

int
fdc_get_drive(fdc_t *fdc)
{
    return (int) fdc->drive;
}

int         fdc_get_bitcell_period(fdc_t *fdc);
int         fdc_get_bit_rate(fdc_t *fdc);
static void fdc_rate(fdc_t *fdc, int drive);

int
fdc_get_perp(fdc_t *fdc)
{
    if (!(fdc->flags & FDC_FLAG_AT) || (fdc->flags & FDC_FLAG_PCJR))
        return 0;

    return (int) fdc->perp;
}

int
fdc_get_gap2(fdc_t *fdc, int drive)
{
    int auto_gap2 = 22;

    if (!(fdc->flags & FDC_FLAG_AT) || (fdc->flags & FDC_FLAG_PCJR))
        return 22;

    if (fdc->perp & 3)
        return ((fdc->perp & 3) == 3) ? 41 : 22;
    else {
        auto_gap2 = (fdc_get_bit_rate(fdc) >= 3) ? 41 : 22;
        return (fdc->perp & (4 << drive)) ? auto_gap2 : 22;
    }
}

int
fdc_get_format_n(fdc_t *fdc)
{
    return (int) fdc->format_n;
}

int
fdc_is_mfm(fdc_t *fdc)
{
    return fdc->mfm ? 1 : 0;
}

int
fdc_is_dma(fdc_t *fdc)
{
    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma)
        return 0;
    else
        return 1;
}

void
fdc_request_next_sector_id(fdc_t *fdc)
{
    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma)
        fdc->stat = 0xf0;
    else {
        dma_set_drq(fdc->dma_ch, 1);
        fdc->stat = 0x50;
    }
}

void
fdc_stop_id_request(fdc_t *fdc)
{
    fdc->stat &= 0x7f;
}

int
fdc_get_gap(fdc_t *fdc)
{
    return (int) fdc->gap;
}

int
fdc_get_dtl(fdc_t *fdc)
{
    return fdc->dtl;
}

int
fdc_get_format_sectors(fdc_t *fdc)
{
    return (int) fdc->format_sectors;
}

static void
fdc_int(fdc_t *fdc, int set_fintr)
{
    int ienable = 0;

    if (fdc->flags & FDC_FLAG_PS2_MCA)
        ienable = 1;
    else if (!(fdc->flags & FDC_FLAG_PCJR))
        ienable = !!(fdc->dor & 8);

    if (ienable) {
        if (fdc->irq != 0xff)
            picint(1 << fdc->irq);

        if (set_fintr)
            fdc->fintr = 1;
    }
    fdc_log("fdc_int(%i): fdc->fintr = %i\n", set_fintr, fdc->fintr);
}

static void
fdc_watchdog_poll(void *priv)
{
    fdc_t *fdc = (fdc_t *) priv;

    fdc->watchdog_count--;
    if (fdc->watchdog_count)
        timer_advance_u64(&fdc->watchdog_timer, 1000 * TIMER_USEC);
    else {
        if ((fdc->dor & 0x20) && (fdc->irq != 0xff))
            picint(1 << fdc->irq);
    }
}

/* fdc->rwc per Winbond W83877F datasheet:
    0 = normal;
    1 = 500 kbps, 360 rpm;
    2 = 500 kbps, 300 rpm;
    3 = 250 kbps

    Drive is only aware of selected rate and densel, so on real hardware, the rate expected by fdc_t and the rate actually being
    processed by drive can mismatch, in which case the fdc_t won't receive the correct data.
*/

void
fdc_update_rates(fdc_t *fdc)
{
    fdc_rate(fdc, 0);
    fdc_rate(fdc, 1);
    fdc_rate(fdc, 2);
    fdc_rate(fdc, 3);
}

void
fdc_set_power_down(fdc_t *fdc, uint8_t power_down)
{
    fdc->power_down = power_down;
}

void
fdc_toggle_flag(fdc_t *fdc, int flag, int on)
{
    if (on)
        fdc->flags |= flag;
    else
        fdc->flags &= ~flag;
}

void
fdc_update_max_track(fdc_t *fdc, int max_track)
{
    fdc->max_track = max_track;
}

void
fdc_update_enh_mode(fdc_t *fdc, int enh_mode)
{
    fdc->enh_mode = !!enh_mode;
    fdc_update_rates(fdc);
}

int
fdc_get_rwc(fdc_t *fdc, int drive)
{
    return fdc->rwc[drive];
}

void
fdc_update_rwc(fdc_t *fdc, int drive, int rwc)
{
    fdc_log("FDD %c: New RWC is %i\n", 0x41 + drive, rwc);
    fdc->rwc[drive] = rwc;
    fdc_rate(fdc, drive);
}

uint8_t
fdc_get_media_id(fdc_t *fdc, int id)
{
    uint8_t ret = fdc->media_id & (1 << id);

    return ret;
}

void
fdc_set_media_id(fdc_t *fdc, int id, int set)
{
    fdc->media_id = (fdc->media_id & ~(1 << id)) | (set << id);
}

void
fdc_set_flags(fdc_t *fdc, int flags)
{
    fdc->flags |= flags;
}

void
fdc_clear_flags(fdc_t *fdc, int flags)
{
    fdc->flags &= ~flags;
}

void
fdc_set_fdd_changed(int drive, int changed)
{
    if (changed)
        fdd_changed[drive] = 1;
}

uint8_t
fdc_get_fdd_changed(int drive)
{
    uint8_t ret = !!fdd_changed[drive];

    return ret;
}

uint8_t
fdc_get_shadow(fdc_t *fdc)
{
    uint8_t ret = (fdc->rate & 0x03) |
        ((fdc->pretrk & 0x07) << 2) |
        (fdc->power_down ? 0x40 : 0x00) |
        ((fdc_read(0x03f2, fdc) & 0x04) ? 0x80 : 0x00);

    return ret;
}

int
fdc_get_boot_drive(fdc_t *fdc)
{
    return fdc->boot_drive;
}

void
fdc_update_boot_drive(fdc_t *fdc, int boot_drive)
{
    fdc->boot_drive = boot_drive;
}

void
fdc_update_densel_polarity(fdc_t *fdc, int densel_polarity)
{
    fdc_log("FDC: New DENSEL polarity is %i\n", densel_polarity);
    fdc->densel_polarity = densel_polarity;
    fdc_update_rates(fdc);
}

uint8_t
fdc_get_densel_polarity(fdc_t *fdc)
{
    return fdc->densel_polarity;
}

void
fdc_update_densel_force(fdc_t *fdc, int densel_force)
{
    fdc_log("FDC: New DENSEL force is %i\n", densel_force);
    fdc->densel_force = densel_force;
    fdc_update_rates(fdc);
}

void
fdc_update_drvrate(fdc_t *fdc, int drive, int drvrate)
{
    fdc_log("FDD %c: New drive rate is %i\n", 0x41 + drive, drvrate);
    fdc->drvrate[drive] = drvrate;
    fdc_rate(fdc, drive);
}

void
fdc_update_drv2en(fdc_t *fdc, int drv2en)
{
    fdc->drv2en = !!drv2en;
}

void
fdc_update_rate(fdc_t *fdc, int drive)
{
    if (((fdc->rwc[drive] == 1) || (fdc->rwc[drive] == 2)) &&
        fdc->enh_mode && !(fdc->flags & FDC_FLAG_SMC661))
        fdc->bit_rate = 500;
    else if ((fdc->rwc[drive] == 3) && fdc->enh_mode &&
        !(fdc->flags & FDC_FLAG_SMC661))
        fdc->bit_rate = 250;
    else  switch (fdc->rate) {
            default:
                break;
            case 0: /*High density*/
                fdc->bit_rate = 500;
                break;
            case 1: /*Double density (360 rpm)*/
                switch (fdc->drvrate[drive]) {
                    default:
                        break;
                    case 0:
                        fdc->bit_rate = 300;
                        break;
                    case 1:
                        fdc->bit_rate = 500;
                        break;
                    case 2:
                        fdc->bit_rate = 2000;
                        break;
                }
                break;
            case 2: /*Double density*/
                fdc->bit_rate = 250;
                break;
            case 3: /*Extended density*/
                fdc->bit_rate = 1000;
                break;
        }

    fdc->bitcell_period = (1000000 / fdc->bit_rate) * 2; /*Bitcell period in ns*/
}

int
fdc_get_bit_rate(fdc_t *fdc)
{
    switch (fdc->bit_rate) {
        case 500:
            return 0;
        case 300:
            return 1;
        case 2000:
            return 1 | 4;
        case 250:
            return 2;
        case 1000:
            return 3;

        default:
            break;
    }
    return 2;
}

int
fdc_get_bitcell_period(fdc_t *fdc)
{
    return fdc->bitcell_period;
}

static int
fdc_get_densel(fdc_t *fdc, int drive)
{
    if (fdc->enh_mode && !(fdc->flags & FDC_FLAG_SMC661)) {
        switch (fdc->rwc[drive]) {
            case 1:
            case 3:
                return 0;
            case 2:
                return 1;

            default:
                break;
        }
    }

    if (!(fdc->flags & FDC_FLAG_NSC)) {
        switch (fdc->densel_force) {
            case 2:
                return 1;
            case 3:
                return 0;

            default:
                break;
        }
    } else {
        switch (fdc->densel_force) {
            case 0:
                return 0;
            case 1:
                return 1;

            default:
                break;
        }
    }

    switch (fdc->rate) {
        case 0:
        case 3:
            return fdc->densel_polarity ? 1 : 0;
        case 1:
        case 2:
            return fdc->densel_polarity ? 0 : 1;

        default:
            break;
    }

    return 0;
}

static void
fdc_rate(fdc_t *fdc, int drive)
{
    fdc_update_rate(fdc, drive);
    fdc_log("FDD %c: [%i] Setting rate: %i, %i, %i (%i, %i, %i)\n", 0x41 + drive, fdc->enh_mode, fdc->drvrate[drive], fdc->rate, fdc_get_densel(fdc, drive), fdc->rwc[drive], fdc->densel_force, fdc->densel_polarity);
    fdd_set_densel(fdc_get_densel(fdc, drive));
    fdc_log("FDD %c: [%i] Densel: %i\n", 0x41 + drive, fdc->enh_mode, fdc_get_densel(fdc, drive));
}

int
real_drive(fdc_t *fdc, int drive)
{
    if (drive < 2)
        return drive ^ fdc->swap;
    else
        return drive;
}

/* FDD notifies FDC when seek operation is complete */
void
fdc_seek_complete_interrupt(fdc_t *fdc, int drive)
{
    if (!fdc) {
        fdc_log("ERROR: fdc_seek_complete_interrupt called with NULL fdc!\n");
        return;
    }

    if (FDC_FLAG_PCJR & fdc->flags) {
        fdc->fintr     = 1;
        fdc->interrupt = -4;
        fdc_callback(fdc);
        return;
    }

    fdc_log("FDD %c: Seek complete interrupt\n", 0x41 + drive);

    fdc->fintr = 1;
    fdc->interrupt = -3;
    fdc->st0   = 0x20 | (drive & 3);
    if (fdd_get_head(drive))
        fdc->st0 |= 0x04;

    fdc_callback(fdc);
}

void
fdc_seek(fdc_t *fdc, int drive, int params)
{
    fdd_seek(real_drive(fdc, drive), params);
    fdc->stat = (fdc->stat & 0x0F) | 0x10 | (1 << fdc->drive);
}

static void
fdc_bad_command(fdc_t *fdc)
{
    fdc->stat      = 0x10;
    fdc->interrupt = 0xfc;
    timer_set_delay_u64(&fdc->timer, 100 * TIMER_USEC);
}

static void
fdc_io_command_phase1(fdc_t *fdc, int out)
{
    fifo_reset(fdc->fifo_p);
    fdc_rate(fdc, fdc->drive);
    fdc->head = fdc->params[2];
    fdd_set_head(real_drive(fdc, fdc->drive), (fdc->params[0] & 4) ? 1 : 0);
    fdc->sector          = fdc->params[3];
    fdc->eot[fdc->drive] = fdc->params[5];
    fdc->gap             = fdc->params[6];
    fdc->dtl             = fdc->params[7];
    fdc->rw_track        = fdc->params[1];

    int implied_seek = 0;
    if (fdc->config & 0x40) {
        if (fdc->rw_track != fdc->pcn[fdc->params[0] & 3]) {
            implied_seek = 1;
            fdc_seek(fdc, fdc->drive, ((int) fdc->rw_track) - ((int) fdc->pcn[fdc->params[0] & 3]));
            fdc->pcn[fdc->params[0] & 3] = fdc->rw_track;
        }
    }

    if (fdc->processed_cmd == 0x05 || fdc->processed_cmd == 0x09)
        ui_sb_update_icon_write(SB_FLOPPY | real_drive(fdc, fdc->drive), 1);
    else
        ui_sb_update_icon(SB_FLOPPY | real_drive(fdc, fdc->drive), 1);

    if (implied_seek && !fdd_get_turbo(real_drive(fdc, fdc->drive))) {
        fdc->stat = (fdc->stat & 0x0F) | 0x10 | (1 << real_drive(fdc, fdc->drive)); /* CB=1, per-drive busy */
        return;
    }

    fdc->stat = out ? 0x10 : 0x50;
    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma) {
        fdc->stat |= 0x20;
        if (out)
            fdc->stat |= 0x80;
    } else
        dma_set_drq(fdc->dma_ch, 1);
}

static void
fdc_sis(fdc_t *fdc)
{
    int drive_num;

    fdc->stat = (fdc->stat & 0xf) | 0xd0;

    if (fdc->reset_stat) {
        drive_num = real_drive(fdc, 4 - fdc->reset_stat);
        if ((drive_num < FDD_NUM) && fdd_get_flags(drive_num)) {
            fdd_stop(drive_num);
            fdd_set_head(drive_num, 0);
            fdc->res[9] = 0xc0 | (4 - fdc->reset_stat) | (fdd_get_head(drive_num) ? 4 : 0);
        } else
            fdc->res[9] = 0xc0 | (4 - fdc->reset_stat);

        fdc->reset_stat--;
    } else {
        if (fdc->fintr) {
            fdc->res[9] = (fdc->st0 & ~0x04) | (fdd_get_head(real_drive(fdc, fdc->drive)) ? 4 : 0);
            fdc->fintr  = 0;
        } else {
            fdc->res[10]    = 0x80;
            fdc->paramstogo = 1;
            return;
        }
    }

    fdc->res[10] = fdc->pcn[fdc->res[9] & 3];

    fdc_log("Sense interrupt status: 2 parameters to go\n");
    fdc->paramstogo = 2;
}

static void
fdc_soft_reset(fdc_t *fdc)
{
    if (fdc->power_down) {
        timer_set_delay_u64(&fdc->timer, 1000 * TIMER_USEC);
        fdc->interrupt = -5;
    } else {
        timer_set_delay_u64(&fdc->timer, 8 * TIMER_USEC);
        fdc->interrupt = -1;

        fdc->perp &= 0xfc;

        for (int i = 0; i < FDD_NUM; i++) {
            ui_sb_update_icon(SB_FLOPPY | i, 0);
            ui_sb_update_icon_write(SB_FLOPPY | i, 0);
        }

        fdc_ctrl_reset(fdc);
    }
}

static void
fdc_write(uint16_t addr, uint8_t val, void *priv)
{
    fdc_t *fdc = (fdc_t *) priv;

    int drive;
    int drive_num;

    fdc_log("Write FDC %04X %02X\n", addr, val);

    cycles -= ISA_CYCLES(8);

    if (!fdc->power_down || ((addr & 7) == 2) || ((addr & 7) == 4))
        switch (addr & 7) {
            case 0:
                return;
            case 1:
                return;
            case 2: /*DOR*/
                if (fdc->flags & FDC_FLAG_PCJR) {
                    if ((fdc->dor & 0x40) && !(val & 0x40)) {
                        timer_set_delay_u64(&fdc->watchdog_timer, 1000 * TIMER_USEC);
                        fdc->watchdog_count = 1000;
                        picintc(1 << fdc->irq);
                    }
                    if ((val & 0x80) && !(fdc->dor & 0x80)) {
                        timer_set_delay_u64(&fdc->timer, 8 * TIMER_USEC);
                        fdc->interrupt = -1;
                        ui_sb_update_icon(SB_FLOPPY | 0, 0);
                        ui_sb_update_icon_write(SB_FLOPPY | 0, 0);
                        fdc_ctrl_reset(fdc);
                    }
                    if (!fdd_get_flags(0))
                        val &= 0xfe;
                    fdd_set_motor_enable(0, val & 0x01);
                    fdc->st0 &= ~0x07;
                    fdc->st0 |= (fdd_get_head(0) ? 4 : 0);
                } else {
                    /*
                       Writing this bit to logic "1" will enable the DRQ,
                       nDACK, TC and FINTR outputs. This bit being a
                       logic "0" will disable the nDACK and TC inputs, and
                       hold the DRQ and FINTR outputs in a high
                       impedance state.
                     */
                    if (!(val & 8) && (fdc->dor & 8) && !(fdc->flags & FDC_FLAG_PS2_MCA)) {
                        fdc->tc    = 1;
                        fdc->fintr = 0;
                        picintc(1 << fdc->irq);
                    }
                    if (!(val & 4)) {
                        fdd_stop(real_drive(fdc, val & 3));
                        fdc->stat = 0x00;
                        fdc->pnum = fdc->ptot = 0;
                    }
                    if ((val & 4) && !(fdc->dor & 4))
                        fdc_soft_reset(fdc);
                    /* We can now simplify this since each motor now spins separately. */
                    for (int i = 0; i < FDD_NUM; i++) {
                        drive_num = real_drive(fdc, i);
                        if ((!fdd_get_flags(drive_num)) || (drive_num >= FDD_NUM))
                            val &= ~(0x10 << drive_num);
                        else
                            fdd_set_motor_enable(i, (val & (0x10 << drive_num)));
                    }
                    drive_num     = real_drive(fdc, val & 0x03);
                    current_drive = drive_num;
                    fdc->st0      = (fdc->st0 & 0xf8) | (val & 0x03) | (fdd_get_head(drive_num) ? 4 : 0);
                }
                fdc->dor = val;
                return;
            case 3: /* TDR */
                if (fdc->enh_mode) {
                    if (fdc->flags & FDC_FLAG_SMC661) {
                        fdc_set_swap(fdc, !!(val & 0x20));
                        fdc_update_densel_force(fdc, (val & 0x18) >> 3);
                    } else {
                        drive = real_drive(fdc, fdc->dor & 3);
                        fdc_update_rwc(fdc, drive, (val & 0x30) >> 4);
                    }
                }
                /* Bit 2: FIFO test mode (PS/55 5550-S,T only. Undocumented)
                   The Power-on Self Test of PS/55 writes and verifies 8 bytes of FIFO buffer through I/O 3F5h.
                   If it fails, then floppy drives will be treated as DD drives. */
                if (fdc->flags & FDC_FLAG_PS2_MCA) {
                    if (val & 0x04) {
                        fdc->tfifo      = 8;
                        fdc->fifointest = 1;
                    } else {
                        fdc->tfifo      = 1;
                        fdc->fifointest = 0;
                    }
                    fifo_reset(fdc->fifo_p);
                    fifo_set_len(fdc->fifo_p, fdc->tfifo + 1);
                    fifo_set_trigger_len(fdc->fifo_p, fdc->tfifo + 1);
                }
                return;
            case 4: /* DSR */
                if (!(fdc->flags & FDC_FLAG_NO_DSR_RESET)) {
                    if (!(val & 0x80)) {
                        timer_set_delay_u64(&fdc->timer, 8 * TIMER_USEC);
                        fdc->interrupt = -6;
                    }
                    if (fdc->power_down || ((val & 0x80) && !(fdc->dsr & 0x80)))
                        fdc_soft_reset(fdc);
                }
                fdc->dsr = val;
                return;
            case 5: /*Command register*/
                if (fdc->fifointest) {
                    /* Write FIFO buffer in the test mode (PS/55) */
                    fdc_log("FIFO buffer position = %X\n", ((fifo_t *) fdc->fifo_p)->end);
                    fifo_write(val, fdc->fifo_p);
                    if (fifo_get_full(fdc->fifo_p))
                        fdc->stat &= ~0x80;
                    break;
                }
                if ((fdc->stat & 0xf0) == 0xb0) {
                    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->fifo) {
                        fdc->dat = val;
                        fdc->stat &= ~0x80;
                    } else {
                        fifo_write(val, fdc->fifo_p);
                        if (fifo_get_full(fdc->fifo_p))
                            fdc->stat &= ~0x80;
                    }
                    break;
                }
                if (fdc->pnum == fdc->ptot) {
                    if ((fdc->stat & 0xf0) != 0x80) {
                        /* If bit 4 of the MSR is set, or the MSR is 0x00,
                           the fdc_t is NOT in the command phase, therefore
                           do NOT accept commands. */
                        return;
                    }

                    fdc->stat &= 0xf;

                    fdc->tc         = 0;
                    fdc->data_ready = 0;

                    fdc->command = val;
                    fdc->stat |= 0x10;
                    fdc_log("Starting FDC command %02X\n", fdc->command);
                    fdc->error = 0;

                    if (((fdc->command & 0x1f) == 0x02) || ((fdc->command & 0x1f) == 0x05) ||
                        ((fdc->command & 0x1f) == 0x06) || ((fdc->command & 0x1f) == 0x0a) ||
                        ((fdc->command & 0x1f) == 0x0c) || ((fdc->command & 0x1f) == 0x0d) ||
                        ((fdc->command & 0x1f) == 0x11) || ((fdc->command & 0x1f) == 0x16) ||
                        ((fdc->command & 0x1f) == 0x19) || ((fdc->command & 0x1f) == 0x1d))
                        fdc->processed_cmd = fdc->command & 0x1f;
                    else
                        fdc->processed_cmd = fdc->command;

                    switch (fdc->processed_cmd) {
                        case 0x01: /*Mode*/
                            if (fdc->flags & FDC_FLAG_NSC) {
                                fdc->pnum = 0;
                                fdc->ptot = 4;
                                fdc->stat |= 0x90;
                                fdc->format_state = 0;
                            } else
                                fdc_bad_command(fdc);
                            break;
                        case 0x02: /*Read track*/
                            fdc->satisfying_sectors = 0;
                            fdc->sc                 = 0;
                            fdc->wrong_am           = 0;
                            fdc->pnum               = 0;
                            fdc->ptot               = 8;
                            fdc->stat |= 0x90;
                            fdc->mfm = (fdc->command & 0x40) ? 1 : 0;
                            break;
                        case 0x03: /*Specify*/
                            fdc->pnum = 0;
                            fdc->ptot = 2;
                            fdc->stat |= 0x90;
                            break;
                        case 0x04: /*Sense drive status*/
                            fdc->pnum = 0;
                            fdc->ptot = 1;
                            fdc->stat |= 0x90;
                            break;
                        case 0x05: /*Write data*/
                        case 0x09: /*Write deleted data*/
                            fdc->satisfying_sectors = 0;
                            fdc->sc                 = 0;
                            fdc->wrong_am           = 0;
                            fdc->deleted            = ((fdc->command & 0x1F) == 9) ? 1 : 0;
                            fdc->pnum               = 0;
                            fdc->ptot               = 8;
                            fdc->stat |= 0x90;
                            fdc->mfm = (fdc->command & 0x40) ? 1 : 0;
                            break;
                        case 0x06: /*Read data*/
                        case 0x0c: /*Read deleted data*/
                        case 0x11: /*Scan equal*/
                        case 0x19: /*Scan low or equal*/
                        case 0x16: /*Verify*/
                        case 0x1d: /*Scan high or equal*/
                            fdc->satisfying_sectors = 0;
                            fdc->sc                 = 0;
                            fdc->wrong_am           = 0;
                            fdc->deleted            = ((fdc->command & 0x1F) == 0xC) ? 1 : 0;
                            if ((fdc->command & 0x1F) == 0x16)
                                fdc->deleted = 2;
                            fdc->deleted |= (fdc->command & 0x20);
                            fdc->pnum = 0;
                            fdc->ptot = 8;
                            fdc->stat |= 0x90;
                            fdc->mfm = (fdc->command & 0x40) ? 1 : 0;
                            break;
                        case 0x17: /*Powerdown mode*/
                            if (!(fdc->flags & FDC_FLAG_ALI)) {
                                fdc_bad_command(fdc);
                                break;
                            }
                            fallthrough;
                        case 0x07: /*Recalibrate*/
                            fdc->pnum = 0;
                            fdc->ptot = 1;
                            fdc->stat |= 0x90;
                            break;
                        case 0x08: /*Sense interrupt status*/
                            fdc_log("fdc->fintr = %i, fdc->reset_stat = %i\n", fdc->fintr, fdc->reset_stat);
                            fdc->lastdrive = fdc->drive;
                            fdc_sis(fdc);
                            break;
                        case 0x0a: /*Read sector ID*/
                            fdc->pnum = 0;
                            fdc->ptot = 1;
                            fdc->stat |= 0x90;
                            fdc->mfm = (fdc->command & 0x40) ? 1 : 0;
                            break;
                        case 0x0d: /*Format track*/
                            fdc->pnum = 0;
                            fdc->ptot = 5;
                            fdc->stat |= 0x90;
                            fdc->mfm          = (fdc->command & 0x40) ? 1 : 0;
                            fdc->format_state = 0;
                            break;
                        case 0x0e: /*Dump registers*/
                            if (fdc->flags & FDC_FLAG_NEC) {
                                fdc_bad_command(fdc);
                                break;
                            }
                            fdc->lastdrive = fdc->drive;
                            fdc->interrupt = 0x0e;
                            fdc_callback(fdc);
                            break;
                        case 0x0f: /*Seek*/
                            fdc->pnum = 0;
                            fdc->ptot = 2;
                            fdc->stat |= 0x90;
                            break;
                        case 0x18: /*NSC*/
                            if (!(fdc->flags & FDC_FLAG_NSC)) {
                                fdc_bad_command(fdc);
                                break;
                            }
                            fallthrough;
                        case 0x10: /*Get version*/
                        case 0x14: /*Unlock*/
                        case 0x94: /*Lock*/
                            if (fdc->flags & FDC_FLAG_NEC) {
                                fdc_bad_command(fdc);
                                break;
                            }
                            fdc->lastdrive = fdc->drive;
                            fdc->interrupt = fdc->command;
                            fdc_callback(fdc);
                            break;
                        case 0x12: /*Set perpendicular mode*/
                            if ((fdc->flags & FDC_FLAG_AT) && !(fdc->flags & FDC_FLAG_PCJR)) {
                                fdc->pnum = 0;
                                fdc->ptot = 1;
                                fdc->stat |= 0x90;
                            } else
                                fdc_bad_command(fdc);
                            break;
                        case 0x13: /*Configure*/
                            if (fdc->flags & FDC_FLAG_NEC) {
                                fdc_bad_command(fdc);
                                break;
                            }
                            fdc->pnum = 0;
                            fdc->ptot = 3;
                            fdc->stat |= 0x90;
                            break;
                        default:
                            fdc_bad_command(fdc);
                            break;
                    }
                } else {
                    fdc->stat                = 0x10 | (fdc->stat & 0xf);
                    fdc->params[fdc->pnum++] = val;
                    if (fdc->pnum == 1) {
                        if (command_has_drivesel[fdc->command & 0x1F]) {
                            if (fdc->flags & FDC_FLAG_PCJR)
                                fdc->drive = 0;
                            else
                                fdc->drive = fdc->dor & 3;
                            fdc->rw_drive = fdc->params[0] & 3;
                            if (((fdc->command & 0x1F) == 7) || ((fdc->command & 0x1F) == 15))
                                fdc->stat |= (1 << real_drive(fdc, fdc->drive));
                        }
                    }
                    if (fdc->pnum == fdc->ptot) {
                        fdc_log("Got all params %02X\n", fdc->command);
                        fifo_reset(fdc->fifo_p);
                        fdc->interrupt  = fdc->processed_cmd;
                        fdc->reset_stat = 0;
                        /* Disable timer if enabled. */
                        timer_disable(&fdc->timer);
                        /* Start timer if needed at this point. */
                        switch (fdc->interrupt & 0x1f) {
                            case 0x02: /* Read a track */
                            case 0x03: /* Specify */
                            case 0x0a: /* Read sector ID */
                            case 0x05: /* Write data */
                            case 0x06: /* Read data */
                            case 0x09: /* Write deleted data */
                            case 0x0c: /* Read deleted data */
                            case 0x11: /* Scan equal */
                            case 0x12: /* Perpendicular mode */
                            case 0x16: /* Verify */
                            case 0x19: /* Scan low or equal */
                            case 0x1d: /* Scan high or equal */
                                /* Do nothing. */
                                break;
                            case 0x07: /* Recalibrate */
                            case 0x0f: /* Seek */
                                if (fdc->flags & FDC_FLAG_PCJR)
                                    timer_set_delay_u64(&fdc->timer, 1000 * TIMER_USEC);
                                else
                                    timer_set_delay_u64(&fdc->timer, 256 * TIMER_USEC);
                                break;
                            default:
                                timer_set_delay_u64(&fdc->timer, 256 * TIMER_USEC);
                                break;
                        }
                        /* Process the firt phase of the command. */
                        switch (fdc->processed_cmd) {
                            case 0x02: /* Read a track */
                                fdc_io_command_phase1(fdc, 0);
                                fdc->read_track_sector.id.c = fdc->params[1];
                                fdc->read_track_sector.id.h = fdc->params[2];
                                fdc->read_track_sector.id.r = 1;
                                fdc->read_track_sector.id.n = fdc->params[4];
                                if ((fdc->head & 0x01) && !fdd_is_double_sided(real_drive(fdc, fdc->drive))) {
                                    fdc_noidam(fdc);
                                    return;
                                }
                                fdd_readsector(real_drive(fdc, fdc->drive), SECTOR_FIRST, fdc->params[1], fdc->head, fdc->rate, fdc->params[4]);
                                break;
                            case 0x03: /* Specify */
                                fdc->stat       = 0x80;
                                fdc->specify[0] = fdc->params[0];
                                fdc->specify[1] = fdc->params[1];
                                fdc->dma        = (fdc->specify[1] & 1) ^ 1;
                                if (!fdc->dma)
                                    dma_set_drq(fdc->dma_ch, 0);
                                break;
                            case 0x04: /*Sense drive status*/
                                fdd_set_head(real_drive(fdc, fdc->drive), (fdc->params[0] & 4) ? 1 : 0);
                                break;
                            case 0x05: /* Write data */
                            case 0x09: /* Write deleted data */
                                fdc_io_command_phase1(fdc, 1);
                                if ((fdc->head & 0x01) && !fdd_is_double_sided(real_drive(fdc, fdc->drive))) {
                                    fdc_noidam(fdc);
                                    return;
                                }
                                fdd_writesector(real_drive(fdc, fdc->drive), fdc->sector, fdc->params[1], fdc->head, fdc->rate, fdc->params[4]);
                                break;
                            case 0x11: /* Scan equal */
                            case 0x19: /* Scan low or equal */
                            case 0x1d: /* Scan high or equal */
                                fdc_io_command_phase1(fdc, 1);
                                if ((fdc->head & 0x01) && !fdd_is_double_sided(real_drive(fdc, fdc->drive))) {
                                    fdc_noidam(fdc);
                                    return;
                                }
                                fdd_comparesector(real_drive(fdc, fdc->drive), fdc->sector, fdc->params[1], fdc->head, fdc->rate, fdc->params[4]);
                                break;
                            case 0x16: /* Verify */
                                if (fdc->params[0] & 0x80)
                                    fdc->sc = fdc->params[7];
                                fallthrough;
                            case 0x06: /* Read data */
                            case 0x0c: /* Read deleted data */
                                fdc_io_command_phase1(fdc, 0);
                                fdc_log("Reading sector (drive %i) (%i) (%i %i %i %i) (%i %i %i)\n", fdc->drive, fdc->params[0], fdc->params[1], fdc->params[2], fdc->params[3], fdc->params[4], fdc->params[5], fdc->params[6], fdc->params[7]);
                                if ((fdc->head & 0x01) && !fdd_is_double_sided(real_drive(fdc, fdc->drive))) {
                                    fdc_noidam(fdc);
                                    return;
                                }
                                if (((dma_mode(2) & 0x0C) == 0x00) && !(fdc->flags & FDC_FLAG_PCJR) && fdc->dma) {
                                    /* DMA is in verify mode, treat this like a VERIFY command. */
                                    fdc_log("Verify-mode read!\n");
                                    fdc->tc = 1;
                                    fdc->deleted |= 2;
                                }
                                fdd_readsector(real_drive(fdc, fdc->drive), fdc->sector, fdc->params[1], fdc->head, fdc->rate, fdc->params[4]);
                                break;

                            case 0x07: /* Recalibrate */
                                fdc->rw_drive = fdc->params[0] & 3;
                                fdc->stat     = (1 << real_drive(fdc, fdc->drive));
                                if (!(fdc->flags & FDC_FLAG_PCJR))
                                    fdc->stat |= 0x80;
                                fdc->st0 = fdc->params[0] & 3;
                                fdc->st0 |= fdd_get_head(real_drive(fdc, fdc->drive)) ? 0x04 : 0x00;
                                fdc->st0 |= 0x80;
                                drive_num = real_drive(fdc, fdc->drive);
                                /* Three conditions under which the command should fail. */
                                if ((drive_num >= FDD_NUM) || !fdd_get_flags(drive_num) || !motoron[drive_num] || fdd_track0(drive_num)) {
                                    fdc_log("Failed recalibrate\n");
                                    if ((drive_num >= FDD_NUM) || !fdd_get_flags(drive_num) || !motoron[drive_num])
                                        fdc->st0 = 0x70 | (fdc->params[0] & 3);
                                    else
                                        fdc->st0 = 0x20 | (fdc->params[0] & 3);
                                    fdc->pcn[fdc->params[0] & 3] = 0;
                                    if (fdc->flags & FDC_FLAG_PCJR) {
                                        fdc->fintr     = 1;
                                        fdc->interrupt = -4;
                                    } else {
                                        timer_disable(&fdc->timer);
                                        fdc->interrupt = -3;
                                        fdc_callback(fdc);
                                    }
                                    break;
                                }
                                if ((real_drive(fdc, fdc->drive) != 1) || fdc->drv2en)
                                    fdc_seek(fdc, fdc->drive, -fdc->max_track);
                                fdc_log("Recalibrating...\n");
                                fdc->seek_dir = fdc->step = 1;
                                break;
                            case 0x0a: /* Read sector ID */
                                fdc_rate(fdc, fdc->drive);
                                fdc->head = (fdc->params[0] & 4) ? 1 : 0;
                                fdd_set_head(real_drive(fdc, fdc->drive), (fdc->params[0] & 4) ? 1 : 0);
                                if ((real_drive(fdc, fdc->drive) != 1) || fdc->drv2en) {
                                    fdd_readaddress(real_drive(fdc, fdc->drive), fdc->head, fdc->rate);
                                    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma)
                                        fdc->stat = 0x70;
                                    else
                                        fdc->stat = 0x50;
                                } else
                                    fdc_noidam(fdc);
                                break;
                            case 0x0d: /* Format */
                                fdc_rate(fdc, fdc->drive);
                                fdc->head = (fdc->params[0] & 4) ? 1 : 0;
                                fdd_set_head(real_drive(fdc, fdc->drive), (fdc->params[0] & 4) ? 1 : 0);
                                fdc->gap            = fdc->params[3];
                                fdc->format_sectors = fdc->params[2];
                                fdc->format_n       = fdc->params[1];
                                fdc->format_state   = 1;
                                fdc->stat           = 0x10;
                                break;
                            case 0x0f: /* Seek */
                                fdc->rw_drive = fdc->params[0] & 3;
                                fdc->stat     = (1 << fdc->drive);
                                if (!(fdc->flags & FDC_FLAG_PCJR))
                                    fdc->stat |= 0x80;
                                fdc->head = 0; /* TODO: See if this is correct. */
                                fdc->st0  = fdc->params[0] & 0x03;
                                fdc->st0 |= (fdc->params[0] & 4);
                                fdc->st0 |= 0x80;
                                fdd_set_head(real_drive(fdc, fdc->drive), (fdc->params[0] & 4) ? 1 : 0);
                                drive_num = real_drive(fdc, fdc->drive);
                                /* Three conditions under which the command should fail. */
                                if (!fdd_get_flags(drive_num) || (drive_num >= FDD_NUM) || !motoron[drive_num]) {
                                    /* Yes, failed SEEK's still report success, unlike failed RECALIBRATE's. */
                                    fdc->st0 = 0x20 | (fdc->params[0] & 3);
                                    if (fdc->command & 0x80) {
                                        if (fdc->command & 0x40)
                                            fdc->pcn[fdc->params[0] & 3] += fdc->params[1];
                                        else
                                            fdc->pcn[fdc->params[0] & 3] -= fdc->params[1];
                                    } else
                                        fdc->pcn[fdc->params[0] & 3] = fdc->params[1];
                                    if (fdc->flags & FDC_FLAG_PCJR) {
                                        fdc->fintr     = 1;
                                        fdc->interrupt = -4;
                                    } else {
                                        timer_disable(&fdc->timer);
                                        fdc->interrupt = -3;
                                        fdc_callback(fdc);
                                    }
                                    break;
                                }
                                if (fdc->command & 0x80) {
                                    if (fdc->params[1]) {
                                        if (fdc->command & 0x40) {
                                            /* Relative seek inwards. */
                                            fdc->seek_dir = 0;
                                            fdc_seek(fdc, fdc->drive, fdc->params[1]);
                                            fdc->pcn[fdc->params[0] & 3] += fdc->params[1];
                                        } else {
                                            /* Relative seek outwards. */
                                            fdc->seek_dir = 1;
                                            fdc_seek(fdc, fdc->drive, -fdc->params[1]);
                                            fdc->pcn[fdc->params[0] & 3] -= fdc->params[1];
                                        }
                                        fdc->step = 1;
                                    } else {
                                        fdc->st0 = 0x20 | (fdc->params[0] & 3);
                                        fdc->fintr     = 1;
                                        fdc->interrupt = -4;
                                        break;
                                    }
                                } else {
                                    fdc_log("Seeking to track %i (PCN = %i)...\n", fdc->params[1], fdc->pcn[fdc->params[0] & 3]);
                                    if ((fdc->params[1] - fdc->pcn[fdc->params[0] & 3]) == 0) {
                                        fdc_log("Failed seek\n");
                                        fdc->st0 = 0x20 | (fdc->params[0] & 3);
                                        /* Always use the PCjr code, so both 386BSD and 1B/V3 work. */
                                        fdc->fintr     = 1;
                                        fdc->interrupt = -4;
                                        break;
                                    }
                                    if (fdc->params[1] > fdc->pcn[fdc->params[0] & 3])
                                        fdc->seek_dir = 0;
                                    else
                                        fdc->seek_dir = 1;
                                    fdc_seek(fdc, fdc->drive, fdc->params[1] - fdc->pcn[fdc->params[0] & 3]);
                                    fdc->pcn[fdc->params[0] & 3] = fdc->params[1];
                                    fdc->step                    = 1;
                                }
                                break;
                            case 0x12: /* Perpendicular mode */
                                fdc->stat = 0x80;
                                if (fdc->params[0] & 0x80)
                                    fdc->perp = fdc->params[0] & 0x3f;
                                else {
                                    fdc->perp &= 0xfc;
                                    fdc->perp |= (fdc->params[0] & 0x03);
                                }
                                return;

                            default:
                                break;
                        }
                    } else
                        fdc->stat = 0x90 | (fdc->stat & 0xf);
                }
                return;
            case 7:
                if (!(fdc->flags & FDC_FLAG_TOSHIBA) && !(fdc->flags & FDC_FLAG_AT) && !(fdc->flags & FDC_FLAG_UMC))
                    return;
                fdc->rate = val & 0x03;
                if (fdc->flags & FDC_FLAG_PS2)
                    fdc->noprec = !!(val & 0x04);
                return;

            default:
                break;
        }
}

uint8_t
fdc_read(uint16_t addr, void *priv)
{
    fdc_t  *fdc = (fdc_t *) priv;
    uint8_t ret = 0xff;
    int     drive = 0;

    cycles -= ISA_CYCLES(8);

    if (!fdc->power_down || ((addr & 7) == 2))
        switch (addr & 7) {
            case 0: /* STA */
                if (fdc->flags & FDC_FLAG_PS2) {
                    drive = real_drive(fdc, fdc->dor & 3);
                    ret   = 0x00;
                    /* TODO:
                            Bit 2: INDEX (best return always 0 as it goes by very fast)
                    */
                    if (fdc->seek_dir)                 /* nDIRECTION */
                        ret |= 0x01;
                    if (writeprot[drive])              /* WRITEPROT */
                        ret |= 0x02;
                    if (!fdd_get_head(drive))          /* nHDSEL */
                        ret |= 0x08;
                    if (fdd_track0(drive))             /* TRK0 */
                        ret |= 0x10;
                    if (fdc->step)                     /* STEP */
                        ret |= 0x20;
                    if (dma_get_drq(fdc->dma_ch))      /* DRQ */
                        ret |= 0x40;
                    if (fdc->fintr || fdc->reset_stat) /* INTR */
                        ret |= 0x80;
                } else if (fdc->flags & FDC_FLAG_PS2_MCA) {
                    drive = real_drive(fdc, fdc->dor & 3);
                    ret   = 0x04;
                    /* TODO:
                            Bit 2: nINDEX (best return always 1 as it goes by very fast)
                    */
                    if (!fdc->seek_dir)                /* DIRECTION */
                        ret |= 0x01;
                    if (!writeprot[drive])             /* nWRITEPROT */
                        ret |= 0x02;
                    if (fdd_get_head(drive))           /* HDSEL */
                        ret |= 0x08;
                    if (!fdd_track0(drive))            /* nTRK0 */
                        ret |= 0x10;
                    if (fdc->step)                     /* STEP */
                        ret |= 0x20;
                    if (!fdd_get_type(1))              /* -Drive 2 Installed */
                        ret |= 0x40;
                    if (fdc->fintr || fdc->reset_stat) /* INTR */
                        ret |= 0x80;
                } else
                    ret = 0xff;
                break;
            case 1: /* STB */
                if (fdc->flags & FDC_FLAG_PS2) {
                    drive = real_drive(fdc, fdc->dor & 3);
                    ret   = 0x00;
                    if (!fdd_get_type(1))              /* -Drive 2 Installed */
                        ret |= 0x80;
                    switch (drive) {                   /* -Drive Select 1,0 */
                        case 0:
                            ret |= 0x43;
                            break;
                        case 1:
                            ret |= 0x23;
                            break;
                        case 2:
                            ret |= 0x62;
                            break;
                        case 3:
                            ret |= 0x61;
                            break;

                        default:
                            break;
                    }
                } else if (fdc->flags & FDC_FLAG_PS2_MCA) {
                    drive = real_drive(fdc, fdc->dor & 3);
                    ret   = 0xc0;
                    ret  |= (fdc->dor & 0x01) << 5;    /* Drive Select 0 */
                    ret  |= (fdc->dor & 0x30) >> 4;    /* Motor Select 1, 0 */
                } else {
                    if (is486 || !fdc->enable_3f1)
                        ret = 0xff;
                    else {
                        if (fdc->flags & FDC_FLAG_UMC) {
                            drive = real_drive(fdc, fdc->dor & 1);
                            ret   = !fdd_is_dd(drive) ? ((fdc->dor & 1) ? 2 : 1) : 0;
                        } else {
                            /* TODO: What is this and what is it used for?
                                     It's almost identical to the PS/2 MCA mode. */
                            drive = real_drive(fdc, fdc->dor & 3);
                            ret   = 0x70;
                            ret  &= ~(drive ? 0x40 : 0x20);
                            ret  |= (fdc->dor & 0x30) >> 4;    /* Motor Select 1, 0 */
                        }
                    }
                }
                break;
            case 2:
                ret = fdc->dor;
                break;
            case 3:
                drive = real_drive(fdc, fdc->dor & 3);
                /* TODO: FDC_FLAG_PS2_TDR? */
                if ((fdc->flags & FDC_FLAG_PS2) || (fdc->flags & FDC_FLAG_PS2_MCA)) {
                    /* PS/1 Model 2121 seems return drive type in port
                     * 0x3f3, despite the 82077AA fdc_t not implementing
                     * this. This is presumably implemented outside the
                     * fdc_t on one of the motherboard's support chips.
                     *
                     * Confirmed: 00=1.44M 3.5
                     *        10=2.88M 3.5
                     *        20=1.2M 5.25
                     *        30=1.2M 5.25
                     *
                     * as reported by Configur.exe.
                     */
                    if (fdd_is_525(drive))
                        ret = 0x20;
                    else if (fdd_is_ed(drive))
                        ret = 0x10;
                    else
                        ret = 0x00;
                    /* PS/55 POST throws an error and halt if ret = 1 or 2, somehow. */
                } else if (!fdc->enh_mode)
                    ret = 0x20;
                else if (fdc->flags & FDC_FLAG_SMC661)
                    ret = (fdc->densel_force << 3) | ((!!fdc->swap) << 5) | (fdc->media_id << 6);
                else
                    ret = (fdc->rwc[drive] << 4) | (fdc->media_id << 6);
                break;
            case 4: /*Status*/
                ret = fdc->stat;
                break;
            case 5: /*Data*/
                if (fdc->fifointest) {
                    /* Read FIFO buffer in the test mode (PS/55) */
                    ret = fifo_read(fdc->fifo_p);
                    break;
                }
                if ((fdc->stat & 0xf0) == 0xf0) {
                    fdc->stat &= ~0x80;
                    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->fifo) {
                        fdc->data_ready = 0;
                        ret             = fdc->dat;
                    } else
                        ret = fifo_read(fdc->fifo_p);
                    break;
                }
                if (fdc->paramstogo) {
                    fdc->stat &= ~0x80;
                    fdc_log("%i parameters to go\n", fdc->paramstogo);
                    fdc->paramstogo--;
                    ret = fdc->res[10 - fdc->paramstogo];
                    if (!fdc->paramstogo)
                        fdc->stat = 0x80;
                    else
                        fdc->stat |= 0xC0;
                } else if (fdc->dma) {
                    ret       = fdc->dat;
                    break;
                } else {
                    fdc->stat &= ~0x80;
                    if (lastbyte)
                        fdc->stat = 0x80;
                    lastbyte        = 0;
                    ret             = fdc->dat;
                    fdc->data_ready = 0;
                }
                fdc->stat &= 0xf0;
                break;
            case 7: /*Disk change*/
                drive = real_drive(fdc, fdc->dor & 3);

                if (fdc->flags & FDC_FLAG_PS2) {
                    if (fdc->dor & (0x10 << drive)) {
                        ret = (fdd_changed[drive] || drive_empty[drive]) ? 0x00 : 0x80;
                        ret |= (fdc->dor & 0x08);
                        ret |= (fdc->noprec << 2);
                        ret |= (fdc->rate & 0x03);
                    } else
                        ret = 0x00;
                } else if (fdc->flags & FDC_FLAG_PS2_MCA) {
                    if (fdc->dor & (0x10 << drive)) {
                        ret = (fdd_changed[drive] || drive_empty[drive]) ? 0x80 : 0x00;
                        ret |= ((fdc->rate & 0x03) << 1);
                        ret |= fdc_get_densel(fdc, drive);
                        ret |= 0x78;
                    } else
                        ret = 0xf9;
                } else {
                    if (fdc->dor & (0x10 << drive)) {
                        if ((drive == 1) && (fdc->flags & FDC_FLAG_TOSHIBA))
                            ret = 0x00;
                        else
                            ret = (fdd_changed[drive] || drive_empty[drive]) ? 0x80 : 0x00;
                    } else
                        ret = 0x00;
                    if (fdc->flags & FDC_FLAG_DISKCHG_ACTLOW) /*PC2086/3086 seem to reverse this bit*/
                        ret ^= 0x80;

                    /* 0 = ????, 1 = Ext. FDD off, 2 = Ext. FDD = FDD A, 3 = Ext. FDD = FDD B */
                    if (fdc->flags & FDC_FLAG_TOSHIBA) {
                        ret |= (3 << 5);
                        ret |= 0x01;
                    } else
                        ret |= 0x7F;
                }

                fdc->step = 0;
                break;
            default:
                ret = 0xff;
        }
    fdc_log("[%04X:%08X] Read FDC %04X %02X [%i:%02X]\n", CS, cpu_state.pc, addr, ret, drive, fdc->dor & (0x10 << drive));
    return ret;
}

static void
fdc_poll_common_finish(fdc_t *fdc, int compare, int st5)
{
    fdc_int(fdc, 1);
    if (!(fdc->flags & FDC_FLAG_FINTR))
        fdc->fintr = 0;
    fdc->stat = 0xD0;
    fdc->st0 = fdc->res[4] = (fdd_get_head(real_drive(fdc, fdc->drive)) ? 4 : 0) | fdc->rw_drive;
    fdc->res[5]            = st5;
    fdc->res[6]            = 0;
    if (fdc->error) {
        fdc->error = 0;
        fdc->st0 |= 0x40;
        fdc->res[4] |= 0x40;
        fdc->res[5] |= fdc->st5;
        fdc->res[6] |= fdc->st6;
    }
    if (fdc->wrong_am) {
        fdc->res[6] |= 0x40;
        fdc->wrong_am = 0;
    }
    if (compare == 1) {
        if (!fdc->satisfying_sectors)
            fdc->res[6] |= 4;
        else if (fdc->satisfying_sectors == (fdc->params[5] << ((fdc->command & 80) ? 1 : 0)))
            fdc->res[6] |= 8;
    } else if (compare == 2) {
        if (fdc->satisfying_sectors & 1)
            fdc->res[5] |= 0x20;
        if (fdc->satisfying_sectors & 2) {
            fdc->res[5] |= 0x20;
            fdc->res[6] |= 0x20;
        }
        if (fdc->satisfying_sectors & 4)
            fdc->res[5] |= 0x04;
        if (fdc->satisfying_sectors & 8) {
            fdc->res[5] |= 0x04;
            fdc->res[6] |= 0x02;
        }
        if (fdc->satisfying_sectors & 0x10) {
            fdc->res[5] |= 0x04;
            fdc->res[6] |= 0x10;
        }
    }
    fdc->res[7]  = fdc->rw_track;
    fdc->res[8]  = fdc->head;
    fdc->res[9]  = fdc->sector;
    fdc->res[10] = fdc->params[4];
    fdc_log("Read/write finish (%02X %02X %02X %02X %02X %02X %02X)\n", fdc->res[4], fdc->res[5], fdc->res[6], fdc->res[7], fdc->res[8], fdc->res[9], fdc->res[10]);
    ui_sb_update_icon(SB_FLOPPY | real_drive(fdc, fdc->drive), 0);
    ui_sb_update_icon_write(SB_FLOPPY | real_drive(fdc, fdc->drive), 0);
    fdc->paramstogo = 7;
    dma_set_drq(fdc->dma_ch, 0);
}

static void
fdc_poll_readwrite_finish(fdc_t *fdc, int compare)
{
    if ((fdc->interrupt == 5) || (fdc->interrupt == 9))
        fdd_do_writeback(real_drive(fdc, fdc->drive));

    fdc->interrupt = -2;

    fdc_poll_common_finish(fdc, compare, 0);
}

static void
fdc_no_dma_end(fdc_t *fdc, int compare)
{
    timer_disable(&fdc->timer);

    fdc_poll_common_finish(fdc, compare, 0x80);
}

static void
fdc_callback(void *priv)
{
    fdc_t *fdc        = (fdc_t *) priv;
    int    compare    = 0;
    int    drive_num  = 0;
    int    old_sector = 0;
    fdc_log("fdc_callback(): %i\n", fdc->interrupt);
    switch (fdc->interrupt) {
        case -3: /*End of command with interrupt*/
        case -4: /*Recalibrate/seek interrupt (PCjr only)*/
            fdc_int(fdc, fdc->interrupt & 1);
            fdc->stat = (fdc->stat & 0xf) | 0x80;
            return;
        case -2: /*End of command*/
            fdc->stat = (fdc->stat & 0xf) | 0x80;
            return;
        case -5: /*Reset in power down mode */
            fdc->perp &= 0xfc;

            for (uint8_t i = 0; i < FDD_NUM; i++) {
                ui_sb_update_icon(SB_FLOPPY | i, 0);
                ui_sb_update_icon_write(SB_FLOPPY | i, 0);
            }

            fdc_ctrl_reset(fdc);

            fdc->fintr = 0;
            memset(fdc->pcn, 0x00, 4 * sizeof(uint16_t));
            return;
        case -1: /*Reset*/
            fdc_int(fdc, 1);
            fdc->fintr = 0;
            memset(fdc->pcn, 0x00, 4 * sizeof(uint16_t));
            fdc->reset_stat = 4;
            return;
        case -6: /*DSR Reset clear*/
            fdc->dsr |= 0x80;
            return;
        case 0x01: /* Mode */
            fdc->stat         = 0x80;
            fdc->densel_force = (fdc->params[2] & 0xC0) >> 6;
            return;
        case 0x02: /* Read track */
            ui_sb_update_icon(SB_FLOPPY | real_drive(fdc, fdc->drive), 1);
            fdc->eot[fdc->drive]--;
            fdc->read_track_sector.id.r++;
            if (!fdc->eot[fdc->drive] || fdc->tc) {
                fdc_poll_readwrite_finish(fdc, 2);
                return;
            } else {
                fdd_readsector(real_drive(fdc, fdc->drive), SECTOR_NEXT, fdc->rw_track, fdc->head, fdc->rate, fdc->params[4]);
                if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma)
                    fdc->stat = 0x70;
                else {
                    dma_set_drq(fdc->dma_ch, 1);
                    fdc->stat = 0x50;
                }
            }
            return;
        case 0x04: /* Sense drive status */
            fdc->res[10] = (fdc->params[0] & 7) | 0x20;
            if (fdd_is_double_sided(real_drive(fdc, fdc->drive)))
                fdc->res[10] |= 0x08;
            if ((real_drive(fdc, fdc->drive) != 1) || fdc->drv2en) {
                if (fdd_track0(real_drive(fdc, fdc->drive)))
                    fdc->res[10] |= 0x10;
            }
            if (writeprot[fdc->drive])
                fdc->res[10] |= 0x40;

            fdc->stat       = (fdc->stat & 0xf) | 0xd0;
            fdc->paramstogo = 1;
            fdc->interrupt  = 0;
            return;
        case 0x05: /* Write data */
        case 0x09: /* Write deleted data */
        case 0x06: /* Read data */
        case 0x0c: /* Read deleted data */
        case 0x11: /* Scan equal */
        case 0x16: /* Verify */
        case 0x19: /* Scan low or equal */
        case 0x1d: /* Scan high or equal */
            if ((fdc->interrupt == 0x11) || (fdc->interrupt == 0x19) || (fdc->interrupt == 0x1D))
                compare = 1;
            else
                compare = 0;
            if ((fdc->interrupt == 6) || (fdc->interrupt == 0xC)) {
                if (fdc->wrong_am && !(fdc->deleted & 0x20)) {
                    /* Mismatching data address mark and no skip, set TC. */
                    fdc->tc = 1;
                }
            }
            old_sector = fdc->sector;
            if (fdc->tc) {
                /* This is needed so that the correct results are returned
                   in case of TC. */
                if (fdc->sector == fdc->params[5]) {
                    if (!(fdc->command & 0x80)) {
                        fdc->rw_track++;
                        fdc->sector = 1;
                    } else {
                        if (fdc->head)
                            fdc->rw_track++;

                        fdc->head ^= 1;
                        fdd_set_head(real_drive(fdc, fdc->drive), fdc->head);
                        fdc->sector = 1;
                    }
                } else
                    fdc->sector++;
                fdc_poll_readwrite_finish(fdc, compare);
                return;
            }
            if ((fdc->interrupt == 0x16) && (fdc->params[0] & 0x80)) {
                /* VERIFY command, EC set */
                fdc->sc--;
                if (!fdc->sc) {
                    fdc->sector++;
                    fdc_poll_readwrite_finish(fdc, 0);
                    return;
                }
                /* The rest is processed normally per MT flag and EOT. */
            } else if ((fdc->interrupt == 0x16) && !(fdc->params[0] & 0x80)) {
                /* VERIFY command, EC clear */
                if ((fdc->sector == old_sector) && (fdc->head == (fdc->command & 0x80) ? 1 : 0)) {
                    fdc->sector++;
                    fdc_poll_readwrite_finish(fdc, 0);
                    return;
                }
            }
            if (fdc->sector == fdc->params[5]) {
                /* Reached end of track, MT bit is clear */
                if (!(fdc->command & 0x80)) {
                    if (fdc->dma) {
                        fdc->rw_track++;
                        fdc->sector = 1;
                    }
                    if (!(fdc->flags & FDC_FLAG_PCJR) && fdc->dma && (old_sector == 255))
                        fdc_no_dma_end(fdc, compare);
                    else
                        fdc_poll_readwrite_finish(fdc, compare);
                    return;
                }
                /* Reached end of track, MT bit is set, head is 1 */
                if (fdd_get_head(real_drive(fdc, fdc->drive)) == 1) {
                    if (fdc->dma) {
                        fdc->rw_track++;
                        fdc->sector = 1;
                        fdc->head &= 0xFE;
                        fdd_set_head(real_drive(fdc, fdc->drive), 0);
                    }
                    if (!(fdc->flags & FDC_FLAG_PCJR) && fdc->dma && (old_sector == 255))
                        fdc_no_dma_end(fdc, compare);
                    else
                        fdc_poll_readwrite_finish(fdc, compare);
                    return;
                }
                if (fdd_get_head(real_drive(fdc, fdc->drive)) == 0) {
                    fdc->sector = 1;
                    fdc->head |= 1;
                    fdd_set_head(real_drive(fdc, fdc->drive), 1);
                    if (!fdd_is_double_sided(real_drive(fdc, fdc->drive))) {
                        fdc_noidam(fdc);
                        return;
                    }
                }
            } else if (fdc->sector < fdc->params[5])
                fdc->sector++;
            else if (fdc->params[5] == 0)
                fdc->sector++;
            if (fdc->interrupt == 0x05 || fdc->interrupt == 0x09)
                ui_sb_update_icon_write(SB_FLOPPY | real_drive(fdc, fdc->drive), 1);
            else
                ui_sb_update_icon(SB_FLOPPY | real_drive(fdc, fdc->drive), 1);
            switch (fdc->interrupt) {
                case 5:
                case 9:
                    fdd_writesector(real_drive(fdc, fdc->drive), fdc->sector, fdc->rw_track, fdc->head, fdc->rate, fdc->params[4]);
                    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma)
                        fdc->stat = 0xb0;
                    else {
                        dma_set_drq(fdc->dma_ch, 1);
                        fdc->stat = 0x10;
                    }
                    break;
                case 6:
                case 0xC:
                case 0x16:
                    fdd_readsector(real_drive(fdc, fdc->drive), fdc->sector, fdc->rw_track, fdc->head, fdc->rate, fdc->params[4]);
                    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma)
                        fdc->stat = 0x70;
                    else {
                        dma_set_drq(fdc->dma_ch, 1);
                        fdc->stat = 0x50;
                    }
                    break;
                case 0x11:
                case 0x19:
                case 0x1D:
                    fdd_comparesector(real_drive(fdc, fdc->drive), fdc->sector, fdc->rw_track, fdc->head, fdc->rate, fdc->params[4]);
                    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma)
                        fdc->stat = 0xb0;
                    else {
                        dma_set_drq(fdc->dma_ch, 1);
                        fdc->stat = 0x10;
                    }
                    break;

                default:
                    break;
            }
            return;
        case 0x07: /* Recalibrate */
            fdc->pcn[fdc->params[0] & 3] = 0;
            drive_num                    = real_drive(fdc, fdc->rw_drive);
            fdc->st0                     = 0x20 | (fdc->params[0] & 3);
            if (!fdd_track0(drive_num))
                fdc->st0 |= 0x50;
            if (fdc->flags & FDC_FLAG_PCJR) {
                fdc->fintr     = 1;
                fdc->interrupt = -4;
            } else
                fdc->interrupt = -3;
            timer_set_delay_u64(&fdc->timer, 2048 * TIMER_USEC);
            fdc->stat = 0x10 | (1 << fdc->rw_drive);
            return;
        case 0x0d: /*Format track*/
            if (fdc->format_state == 1) {
                fdc->format_state = 2;
                timer_set_delay_u64(&fdc->timer, 8 * TIMER_USEC);
            } else if (fdc->format_state == 2) {
                fdd_format(real_drive(fdc, fdc->drive), fdc->head, fdc->rate, fdc->params[4]);
                fdc->format_state = 3;
            } else {
                fdc->interrupt = -2;
                fdc_int(fdc, 1);
                if (!(fdc->flags & FDC_FLAG_FINTR))
                    fdc->fintr = 0;
                fdc->stat = 0xD0;
                fdc->st0 = fdc->res[4] = (fdd_get_head(real_drive(fdc, fdc->drive)) ? 4 : 0) | fdc->drive;
                fdc->res[5] = fdc->res[6] = 0;
                fdc->res[7]               = fdc->format_sector_id.id.c;
                fdc->res[8]               = fdc->format_sector_id.id.h;
                fdc->res[9]               = fdc->format_sector_id.id.r;
                fdc->res[10]              = fdc->format_sector_id.id.n;
                fdc->paramstogo           = 7;
                fdc->format_state         = 0;
                return;
            }
            return;
        case 0x0e: /*Dump registers*/
            fdc->stat       = (fdc->stat & 0xf) | 0xd0;
            fdc->res[1]     = fdc->pcn[0];
            fdc->res[2]     = fdc->pcn[1];
            fdc->res[3]     = fdc->pcn[2];
            fdc->res[4]     = fdc->pcn[3];
            fdc->res[5]     = fdc->specify[0];
            fdc->res[6]     = fdc->specify[1];
            fdc->res[7]     = fdc->eot[fdc->drive];
            fdc->res[8]     = (fdc->perp & 0x7f) | ((fdc->lock) ? 0x80 : 0);
            fdc->res[9]     = fdc->config;
            fdc->res[10]    = fdc->pretrk;
            fdc->paramstogo = 10;
            fdc->interrupt  = 0;
            return;
        case 0x0f: /*Seek*/
            fdc->st0  = 0x20 | (fdc->params[0] & 3);
            fdc->stat = 0x10 | (1 << fdc->rw_drive);
            if (fdd_get_turbo(real_drive(fdc, fdc->rw_drive))) {
                if (fdc->flags & FDC_FLAG_PCJR) {
                    fdc->fintr     = 1;
                    fdc->interrupt = -4;
                    timer_set_delay_u64(&fdc->timer, 1024 * TIMER_USEC);
                } else {
                    fdc->interrupt = -3;
                    fdc_callback(fdc);
                }
            }
            // Interrupts and callbacks in the fdd callback function
            return;
        case 0x10: /*Version*/
        case 0x18: /*NSC*/
            fdc->stat       = (fdc->stat & 0xf) | 0xd0;
            fdc->res[10]    = (fdc->interrupt & 0x08) ? 0x73 : 0x90;
            fdc->paramstogo = 1;
            fdc->interrupt  = 0;
            return;
        case 0x17: /*Powerdown mode*/
            fdc->stat       = (fdc->stat & 0xf) | 0xd0;
            fdc->res[10]    = fdc->params[0];
            fdc->paramstogo = 1;
            fdc->interrupt  = 0;
            return;
        case 0x13: /*Configure*/
            fdc->config = fdc->params[1];
            fdc->pretrk = fdc->params[2];
            fdc->fifo   = (fdc->params[1] & 0x20) ? 0 : 1;
            fdc->tfifo  = (fdc->params[1] & 0xF);
            fifo_reset(fdc->fifo_p);
            fifo_set_len(fdc->fifo_p, fdc->tfifo + 1);
            fifo_set_trigger_len(fdc->fifo_p, fdc->tfifo + 1);
            fdc->stat   = 0x80;
            return;
        case 0x14: /*Unlock*/
        case 0x94: /*Lock*/
            fdc->lock       = (fdc->interrupt & 0x80) ? 1 : 0;
            fdc->stat       = (fdc->stat & 0xf) | 0xd0;
            fdc->res[10]    = (fdc->interrupt & 0x80) ? 0x10 : 0x00;
            fdc->paramstogo = 1;
            fdc->interrupt  = 0;
            return;
        case 0xfc: /*Invalid*/
            fdc->dat = fdc->st0 = 0x80;
            fdc->stat           = (fdc->stat & 0xf) | 0xd0;
            fdc->res[10]        = fdc->st0;
            fdc->paramstogo     = 1;
            fdc->interrupt      = 0;
            return;

        default:
            break;
    }
}

void
fdc_error(fdc_t *fdc, int st5, int st6)
{
    dma_set_drq(fdc->dma_ch, 0);
    timer_disable(&fdc->timer);

    fdc_int(fdc, 1);
    if (!(fdc->flags & FDC_FLAG_FINTR))
        fdc->fintr = 0;
    fdc->stat = 0xD0;
    fdc->st0 = fdc->res[4] = 0x40 | (fdd_get_head(real_drive(fdc, fdc->drive)) ? 4 : 0) | fdc->rw_drive;
    if (fdc->head && !fdd_is_double_sided(real_drive(fdc, fdc->drive)))
        fdc->st0 |= 0x08;
    fdc->res[5] = st5;
    fdc->res[6] = st6;
    if (fdc->wrong_am) {
        fdc->res[6] |= 0x40;
        fdc->wrong_am = 0;
    }
    fdc_log("FDC Error: %02X %02X %02X\n", fdc->res[4], fdc->res[5], fdc->res[6]);
    switch (fdc->interrupt) {
        case 0x02:
        case 0x05:
        case 0x06:
        case 0x09:
        case 0x0C:
        case 0x11:
        case 0x16:
        case 0x19:
        case 0x1D:
            fdc->res[7]  = fdc->rw_track;
            fdc->res[8]  = fdc->head;
            fdc->res[9]  = fdc->sector;
            fdc->res[10] = fdc->params[4];
            break;
        default:
            fdc->res[7]  = 0;
            fdc->res[8]  = 0;
            fdc->res[9]  = 0;
            fdc->res[10] = 0;
            break;
    }
    ui_sb_update_icon(SB_FLOPPY | real_drive(fdc, fdc->drive), 0);
    ui_sb_update_icon_write(SB_FLOPPY | real_drive(fdc, fdc->drive), 0);
    fdc->paramstogo = 7;
}

void
fdc_overrun(fdc_t *fdc)
{
    fdd_stop(fdc->drive);

    fdc_error(fdc, 0x10, 0);
}

int
fdc_is_verify(fdc_t *fdc)
{
    return (fdc->deleted & 2) ? 1 : 0;
}

int
fdc_data(fdc_t *fdc, uint8_t data, int last)
{
    int result = 0;

    if (fdc->deleted & 2) {
        /* We're in a VERIFY command, so return with 0. */
        return 0;
    }

    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma) {
        if (fdc->tc)
            return 0;

        if (fdc->data_ready) {
            fdc_overrun(fdc);
            return -1;
        }

        if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->fifo || (fdc->tfifo < 1)) {
            fdc->dat        = data;
            fdc->data_ready = 1;
            fdc->stat       = 0xf0;
        } else {
            /* FIFO enabled */
            fifo_write(data, fdc->fifo_p);
            if (fifo_get_full(fdc->fifo_p)) {
                /* We have wrapped around, means FIFO is over */
                fdc->data_ready = 1;
                fdc->stat       = 0xf0;
            }
        }
    } else {
        if (fdc->tc)
            return -1;

        if (!fdc->fifo || (fdc->tfifo < 1)) {
            fdc->data_ready = 1;
            fdc->stat       = 0x50;
            dma_set_drq(fdc->dma_ch, 1);

            fdc->dat = data;
            result = dma_channel_write(fdc->dma_ch, data);

            if (result & DMA_OVER) {
                dma_set_drq(fdc->dma_ch, 0);
                fdc->tc = 1;
                return -1;
            }
            dma_set_drq(fdc->dma_ch, 0);
        } else {
            /* FIFO enabled */
            fifo_write(data, fdc->fifo_p);
            if (last || fifo_get_full(fdc->fifo_p)) {
                /* We have wrapped around, means FIFO is over */
                fdc->data_ready = 1;
                fdc->stat       = 0x50;
                dma_set_drq(fdc->dma_ch, 1);

                while (!fifo_get_empty(fdc->fifo_p)) {
                    result = dma_channel_write(fdc->dma_ch, fifo_read(fdc->fifo_p));

                    if (result & DMA_OVER) {
                        dma_set_drq(fdc->dma_ch, 0);
                        fdc->tc = 1;
                        return -1;
                    }
                }
                dma_set_drq(fdc->dma_ch, 0);
            }
        }
    }

    return 0;
}

void
fdc_track_finishread(fdc_t *fdc, int condition)
{
    fdc->stat = 0x10;
    fdc->satisfying_sectors |= condition;
    fdc_callback(fdc);
}

void
fdc_sector_finishcompare(fdc_t *fdc, int satisfying)
{
    fdc->stat = 0x10;
    if (satisfying)
        fdc->satisfying_sectors++;
    fdc_callback(fdc);
}

void
fdc_sector_finishread(fdc_t *fdc)
{
    fdc->stat   = 0x10;
    fdc_callback(fdc);
}

/* There is no sector ID. */
void
fdc_noidam(fdc_t *fdc)
{
    fdc_error(fdc, 1, 0);
}

/* Sector ID's are there, but there is no sector. */
void
fdc_nosector(fdc_t *fdc)
{
    fdc_error(fdc, 4, 0);
}

/* There is no sector data. */
void
fdc_nodataam(fdc_t *fdc)
{
    fdc_error(fdc, 1, 1);
}

/* Abnormal termination with both status 1 and 2 set to 0, used when abnormally
   terminating the fdc_t FORMAT TRACK command. */
void
fdc_cannotformat(fdc_t *fdc)
{
    fdc_error(fdc, 0, 0);
}

void
fdc_datacrcerror(fdc_t *fdc)
{
    fdc_error(fdc, 0x20, 0x20);
}

void
fdc_headercrcerror(fdc_t *fdc)
{
    fdc_error(fdc, 0x20, 0);
}

void
fdc_wrongcylinder(fdc_t *fdc)
{
    fdc_error(fdc, 4, 0x10);
}

void
fdc_badcylinder(fdc_t *fdc)
{
    fdc_error(fdc, 4, 0x02);
}

void
fdc_writeprotect(fdc_t *fdc)
{
    fdc_error(fdc, 0x02, 0);
}

int
fdc_getdata(fdc_t *fdc, int last)
{
    int data = 0;

    if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->dma) {
        if ((fdc->flags & FDC_FLAG_PCJR) || !fdc->fifo || (fdc->tfifo < 1)) {
            data = fdc->dat;

            if (!last)
                fdc->stat = 0xb0;
        } else {
            data = fifo_read(fdc->fifo_p);

            if (!last && fifo_get_empty(fdc->fifo_p))
                fdc->stat = 0xb0;
        }
    } else {
        if (!fdc->fifo || (fdc->tfifo < 1)) {
            data = dma_channel_read(fdc->dma_ch);
            dma_set_drq(fdc->dma_ch, 0);

            if (data & DMA_OVER)
                fdc->tc = 1;

            if (!last) {
                dma_set_drq(fdc->dma_ch, 1);
                fdc->stat = 0x10;
            }
        } else {
            if (fifo_get_empty(fdc->fifo_p)) {
                while (!fifo_get_full(fdc->fifo_p)) {
                    data            = dma_channel_read(fdc->dma_ch);
                    fifo_write(data, fdc->fifo_p);

                    if (data & DMA_OVER) {
                        dma_set_drq(fdc->dma_ch, 0);
                        fdc->tc = 1;
                        break;
                    }
                }
                dma_set_drq(fdc->dma_ch, 0);
            }

            data = fifo_read(fdc->fifo_p);

            if (!last && fifo_get_empty(fdc->fifo_p)) {
                dma_set_drq(fdc->dma_ch, 1);
                fdc->stat = 0x10;
            }
        }
    }

    return data & 0xff;
}

void
fdc_sectorid(fdc_t *fdc, uint8_t track, uint8_t side, uint8_t sector, uint8_t size, UNUSED(uint8_t crc1), UNUSED(uint8_t crc2))
{
    fdc_int(fdc, 1);
    fdc->stat = 0xD0;
    fdc->st0 = fdc->res[4] = (fdd_get_head(real_drive(fdc, fdc->drive)) ? 4 : 0) | fdc->drive;
    fdc->res[5]            = 0;
    fdc->res[6]            = 0;
    fdc->res[7]            = track;
    fdc->res[8]            = side;
    fdc->res[9]            = sector;
    fdc->res[10]           = size;
    ui_sb_update_icon(SB_FLOPPY | real_drive(fdc, fdc->drive), 0);
    fdc->paramstogo = 7;
    dma_set_drq(fdc->dma_ch, 0);
}

uint8_t
fdc_get_swwp(fdc_t *fdc)
{
    return fdc->swwp;
}

void
fdc_set_swwp(fdc_t *fdc, uint8_t swwp)
{
    fdc->swwp = swwp;
}

uint8_t
fdc_get_diswr(fdc_t *fdc)
{
    if (!fdc)
        return 0;

    return fdc->disable_write;
}

void
fdc_set_diswr(fdc_t *fdc, uint8_t diswr)
{
    fdc->disable_write = diswr;
}

uint8_t
fdc_get_swap(fdc_t *fdc)
{
    return fdc->swap;
}

void
fdc_set_swap(fdc_t *fdc, uint8_t swap)
{
    fdc->swap = swap;
}

void
fdc_set_irq(fdc_t *fdc, int irq)
{
    fdc->irq = irq;
}

void
fdc_set_dma_ch(fdc_t *fdc, int dma_ch)
{
    fdc->dma_ch = dma_ch;
}

void
fdc_set_base(fdc_t *fdc, int base)
{
    int super_io = (fdc->flags & FDC_FLAG_SUPERIO);

    if (base == 0x0000) {
        fdc->base_address = base;
        return;
    }

    if (fdc->flags & FDC_FLAG_NSC) {
        io_sethandler(base + 2, 0x0004, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
        io_sethandler(base + 7, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
    } else {
        if ((fdc->flags & FDC_FLAG_AT) || (fdc->flags & FDC_FLAG_AMSTRAD)) {
            io_sethandler(base + (super_io ? 2 : 0), super_io ? 0x0004 : 0x0006, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
            io_sethandler(base + 7, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
        } else {
            if (fdc->flags & FDC_FLAG_PCJR)
                io_sethandler(base, 0x0010, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
            else {
                if (fdc->flags & FDC_FLAG_UMC)
                    io_sethandler(base + 0x0001, 0x0001, fdc_read, NULL, NULL, NULL, NULL, NULL, fdc);
                io_sethandler(base + 0x0002, 0x0001, NULL, NULL, NULL, fdc_write, NULL, NULL, fdc);
                io_sethandler(base + 0x0004, 0x0001, fdc_read, NULL, NULL, NULL, NULL, NULL, fdc);
                io_sethandler(base + 0x0005, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
                if ((fdc->flags & FDC_FLAG_TOSHIBA) || (fdc->flags & FDC_FLAG_UMC))
                    io_sethandler(base + 0x0007, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
            }
        }
    }
    fdc->base_address = base;
    fdc_log("FDC Base address set%s (%04X)\n", super_io ? " for Super I/O" : "", fdc->base_address);
}

void
fdc_remove(fdc_t *fdc)
{
    int super_io = (fdc->flags & FDC_FLAG_SUPERIO);

    if (fdc->base_address == 0x0000)
        return;

    fdc_log("FDC Removed (%04X)\n", fdc->base_address);
    if (fdc->flags & FDC_FLAG_NSC) {
        io_removehandler(fdc->base_address + 2, 0x0004, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
        io_removehandler(fdc->base_address + 7, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
    } else {
        if ((fdc->flags & FDC_FLAG_AT) || (fdc->flags & FDC_FLAG_AMSTRAD)) {
            io_removehandler(fdc->base_address + (super_io ? 2 : 0), super_io ? 0x0004 : 0x0006, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
            io_removehandler(fdc->base_address + 7, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
        } else {
            if (fdc->flags & FDC_FLAG_PCJR)
                io_removehandler(fdc->base_address, 0x0010, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
            else {
                if (fdc->flags & FDC_FLAG_UMC)
                    io_removehandler(fdc->base_address + 0x0001, 0x0001, fdc_read, NULL, NULL, NULL, NULL, NULL, fdc);
                io_removehandler(fdc->base_address + 0x0002, 0x0001, NULL, NULL, NULL, fdc_write, NULL, NULL, fdc);
                io_removehandler(fdc->base_address + 0x0004, 0x0001, fdc_read, NULL, NULL, NULL, NULL, NULL, fdc);
                io_removehandler(fdc->base_address + 0x0005, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
                if ((fdc->flags & FDC_FLAG_TOSHIBA) || (fdc->flags & FDC_FLAG_UMC))
                    io_removehandler(fdc->base_address + 0x0007, 0x0001, fdc_read, NULL, NULL, fdc_write, NULL, NULL, fdc);
            }
        }
    }
}

void
fdc_reset(void *priv)
{
    uint8_t default_rwc;

    fdc_t *fdc = (fdc_t *) priv;

    default_rwc = (fdc->flags & FDC_FLAG_START_RWC_1) ? 1 : 0;

    fdc->enable_3f1 = 1;

    fdc_update_enh_mode(fdc, 0);
    if (fdc->flags & FDC_FLAG_DENSEL_INVERT)
        fdc_update_densel_polarity(fdc, 0);
    else
        fdc_update_densel_polarity(fdc, 1);
    if (fdc->flags & FDC_FLAG_NSC)
        fdc_update_densel_force(fdc, 3);
    else
        fdc_update_densel_force(fdc, 0);
    fdc_update_rwc(fdc, 0, default_rwc);
    fdc_update_rwc(fdc, 1, default_rwc);
    fdc_update_rwc(fdc, 2, default_rwc);
    fdc_update_rwc(fdc, 3, default_rwc);
    /*
       The OKI IF386SX natively supports the Japanese 1.25 MB floppy format,
       since it can read such images just fine, it also attempts to use data
       rate 01 on a 3.5" MB drive (which is the only kind it can physically
       take, anyway), and rate 01 on a 3.5" MB drive is usually used by 3-mode
       drives to switch to 360 RPM. Hence why I'm switching DRVDEN to 1, so
       rate 01 becomes 500 kbps, so on a 3-mode 3.5" drive, 1.25 MB floppies
       can be read. The side effect is that to read 5.25" 360k drives, you
       need to use a dual-RPM 5.25" drive - but hey, that finally gets those
       drives some usage as well.
     */
    fdc_update_drvrate(fdc, 0, (machines[machine].init == machine_at_if386sx_init));
    fdc_update_drvrate(fdc, 1, (machines[machine].init == machine_at_if386sx_init));
    fdc_update_drvrate(fdc, 2, (machines[machine].init == machine_at_if386sx_init));
    fdc_update_drvrate(fdc, 3, (machines[machine].init == machine_at_if386sx_init));
    fdc_update_drv2en(fdc, 1);
    fdc_update_rates(fdc);

    fdc->fifo  = 0;
    fdc->tfifo = 1;
    fdc->fifointest = 0;

    if (fdc->flags & FDC_FLAG_PCJR) {
        fdc->dma        = 0;
        fdc->specify[1] = 1;
    } else if (fdc->flags & FDC_FLAG_SEC) {
        fdc->dma        = 1;
        fdc->specify[1] = 0;
    } else if (fdc->flags & FDC_FLAG_TER) {
        fdc->dma        = 1;
        fdc->specify[1] = 0;
    } else if (fdc->flags & FDC_FLAG_QUA) {
        fdc->dma        = 1;
        fdc->specify[1] = 0;
    } else {
        fdc->dma        = 1;
        fdc->specify[1] = 0;
    }
    fdc->config = 0x20;
    fdc->pretrk = 0;

    fdc->swwp          = 0;
    fdc->disable_write = 0;

    fdc->lock          = 0;

    fdc_ctrl_reset(fdc);

    if (!(fdc->flags & FDC_FLAG_AT))
        fdc->rate = 2;

    fdc->max_track = (fdc->flags & FDC_FLAG_MORE_TRACKS) ? 85 : 79;

    fdc_remove(fdc);
    if (fdc->flags & FDC_FLAG_SEC)
        fdc_set_base(fdc, FDC_SECONDARY_ADDR);
    else if (fdc->flags & FDC_FLAG_TER)
        fdc_set_base(fdc, FDC_TERTIARY_ADDR);
    else if (fdc->flags & FDC_FLAG_QUA)
        fdc_set_base(fdc, FDC_QUATERNARY_ADDR);
    else
        fdc_set_base(fdc, (fdc->flags & FDC_FLAG_PCJR) ? FDC_PRIMARY_PCJR_ADDR : FDC_PRIMARY_ADDR);

    current_drive = 0;

    for (uint8_t i = 0; i < FDD_NUM; i++) {
        ui_sb_update_icon(SB_FLOPPY | i, 0);
        ui_sb_update_icon_write(SB_FLOPPY | i, 0);
    }

    fdc->power_down = 0;

    fdc->media_id   = 0;
}

static void
fdc_close(void *priv)
{
    fdc_t *fdc = (fdc_t *) priv;

    /* Stop timers. */
    timer_disable(&fdc->watchdog_timer);
    timer_disable(&fdc->timer);

    fifo_close(fdc->fifo_p);

    fdcinited = 0;

    free(fdc);
}

static void *
fdc_init(const device_t *info)
{
    fdc_t *fdc = (fdc_t *) calloc(1, sizeof(fdc_t));

    fdc->flags = info->local;

    if (fdc->flags & FDC_FLAG_SEC)
        fdc->irq = FDC_SECONDARY_IRQ;
    else if (fdc->flags & FDC_FLAG_TER)
        fdc->irq = FDC_TERTIARY_IRQ;
    else if (fdc->flags & FDC_FLAG_QUA)
        fdc->irq = FDC_QUATERNARY_IRQ;
    else
        fdc->irq = FDC_PRIMARY_IRQ;

    if (fdc->flags & FDC_FLAG_PCJR)
        timer_add(&fdc->watchdog_timer, fdc_watchdog_poll, fdc, 0);
    else if (fdc->flags & FDC_FLAG_SEC)
        fdc->dma_ch = FDC_SECONDARY_DMA;
    else if (fdc->flags & FDC_FLAG_TER)
        fdc->dma_ch = FDC_TERTIARY_DMA;
    else if (fdc->flags & FDC_FLAG_QUA)
        fdc->dma_ch = FDC_QUATERNARY_DMA;
    else
        fdc->dma_ch = FDC_PRIMARY_DMA;

    fdc_log("FDC added: %04X (flags: %08X)\n", fdc->base_address, fdc->flags);

    fdc->fifo_p = (void *) fifo16_init();

    timer_add(&fdc->timer, fdc_callback, fdc, 0);

    d86f_set_fdc(fdc);
    fdi_set_fdc(fdc);
    fdd_set_fdc(fdc);
    imd_set_fdc(fdc);
    img_set_fdc(fdc);
    mfm_set_fdc(fdc);

    fdc_reset(fdc);

    fdcinited = 1;

    return fdc;
}

void
fdc_3f1_enable(fdc_t *fdc, int enable)
{
    fdc->enable_3f1 = !!enable;
}

const device_t fdc_xt_device = {
    .name          = "PC/XT Floppy Drive Controller",
    .internal_name = "fdc_xt",
    .flags         = 0,
    .local         = 0,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_xt_sec_device = {
    .name          = "PC/XT Floppy Drive Controller (Secondary)",
    .internal_name = "fdc_xt_sec",
    .flags         = FDC_FLAG_SEC,
    .local         = 0,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_xt_ter_device = {
    .name          = "PC/XT Floppy Drive Controller (Tertiary)",
    .internal_name = "fdc_xt_ter",
    .flags         = FDC_FLAG_TER,
    .local         = 0,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_xt_qua_device = {
    .name          = "PC/XT Floppy Drive Controller (Quaternary)",
    .internal_name = "fdc_xt_qua",
    .flags         = FDC_FLAG_QUA,
    .local         = 0,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_xt_t1x00_device = {
    .name          = "PC/XT Floppy Drive Controller (Toshiba)",
    .internal_name = "fdc_xt_t1x00",
    .flags         = 0,
    .local         = FDC_FLAG_TOSHIBA,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_xt_amstrad_device = {
    .name          = "PC/XT Floppy Drive Controller (Amstrad)",
    .internal_name = "fdc_xt_amstrad",
    .flags         = 0,
    .local         = FDC_FLAG_DISKCHG_ACTLOW | FDC_FLAG_AMSTRAD,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_xt_tandy_device = {
    .name          = "PC/XT Floppy Drive Controller (Tandy)",
    .internal_name = "fdc_xt_tandy",
    .flags         = 0,
    .local         = FDC_FLAG_AMSTRAD,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_xt_umc_um8398_device = {
    .name          = "PC/XT Floppy Drive Controller (UMC UM8398)",
    .internal_name = "fdc_xt_umc_um8398",
    .flags         = 0,
    .local         = FDC_FLAG_UMC,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_pcjr_device = {
    .name          = "PCjr Floppy Drive Controller",
    .internal_name = "fdc_pcjr",
    .flags         = 0,
    .local         = FDC_FLAG_PCJR,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_device = {
    .name          = "PC/AT Floppy Drive Controller",
    .internal_name = "fdc_at",
    .flags         = 0,
    .local         = FDC_FLAG_AT,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_sec_device = {
    .name          = "PC/AT Floppy Drive Controller (Secondary)",
    .internal_name = "fdc_at_sec",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_SEC,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_ter_device = {
    .name          = "PC/AT Floppy Drive Controller (Tertiary)",
    .internal_name = "fdc_at_ter",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_TER,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_qua_device = {
    .name          = "PC/AT Floppy Drive Controller (Quaternary)",
    .internal_name = "fdc_at_qua",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_QUA,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_actlow_device = {
    .name          = "PC/AT Floppy Drive Controller (Active low)",
    .internal_name = "fdc_at_actlow",
    .flags         = 0,
    .local         = FDC_FLAG_DISKCHG_ACTLOW | FDC_FLAG_AT,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_smc_661_device = {
    .name          = "PC/AT Floppy Drive Controller (SM(s)C FDC37C661/2)",
    .internal_name = "fdc_at_smc",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_SUPERIO | FDC_FLAG_SMC661,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_smc_device = {
    .name          = "PC/AT Floppy Drive Controller (SM(s)C FDC37Cxxx)",
    .internal_name = "fdc_at_smc",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_SUPERIO,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_ali_device = {
    .name          = "PC/AT Floppy Drive Controller (ALi M512x/M1543C)",
    .internal_name = "fdc_at_ali",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_SUPERIO | FDC_FLAG_ALI,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_winbond_device = {
    .name          = "PC/AT Floppy Drive Controller (Winbond W83x77F)",
    .internal_name = "fdc_at_winbond",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_SUPERIO | FDC_FLAG_START_RWC_1 | FDC_FLAG_MORE_TRACKS,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_nsc_device = {
    .name          = "PC/AT Floppy Drive Controller (NSC PC8730x)",
    .internal_name = "fdc_at_nsc",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_MORE_TRACKS | FDC_FLAG_NSC,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_at_nsc_dp8473_device = {
    .name          = "PC/AT Floppy Drive Controller (NSC DP8473)",
    .internal_name = "fdc_at_nsc_dp8473",
    .flags         = 0,
    .local         = FDC_FLAG_AT | FDC_FLAG_NEC | FDC_FLAG_NO_DSR_RESET,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_ps2_device = {
    .name          = "PS/2 Model 25/30 Floppy Drive Controller",
    .internal_name = "fdc_ps2",
    .flags         = 0,
    .local         = FDC_FLAG_FINTR | FDC_FLAG_DENSEL_INVERT | FDC_FLAG_NO_DSR_RESET | FDC_FLAG_DISKCHG_ACTLOW |
                     FDC_FLAG_AT | FDC_FLAG_PS2,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};

const device_t fdc_ps2_mca_device = {
    .name          = "PS/2 MCA Floppy Drive Controller",
    .internal_name = "fdc_ps2_mca",
    .flags         = 0,
    .local         = FDC_FLAG_FINTR | FDC_FLAG_DENSEL_INVERT | FDC_FLAG_NO_DSR_RESET | FDC_FLAG_AT |
                     FDC_FLAG_PS2_MCA,
    .init          = fdc_init,
    .close         = fdc_close,
    .reset         = fdc_reset,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};